 /*                                                                      
 Copyright 2017 Silicon Integrated Microelectronics, Inc.                
                                                                         
 Licensed under the Apache License, Version 2.0 (the "License");         
 you may not use this file except in compliance with the License.        
 You may obtain a copy of the License at                                 
                                                                         
     http://www.apache.org/licenses/LICENSE-2.0                          
                                                                         
  Unless required by applicable law or agreed to in writing, software    
 distributed under the License is distributed on an "AS IS" BASIS,       
 WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 See the License for the specific language governing permissions and     
 limitations under the License.                                          
 */                                                                      
                                                                         
                                                                         
                                                                         
/////////////////////////////////////////////////////////////////////
////                                                             ////
////  WISHBONE rev.B2 compliant I2C Master bit-controller        ////
////                                                             ////
////                                                             ////
////  Author: Richard Herveille                                  ////
////          richard@asics.ws                                   ////
////          www.asics.ws                                       ////
////                                                             ////
////  Downloaded from: http://www.opencores.org/projects/i2c/    ////
////                                                             ////
/////////////////////////////////////////////////////////////////////
////                                                             ////
//// Copyright (C) 2001 Richard Herveille                        ////
////                    richard@asics.ws                         ////
////                                                             ////
//// This source file may be used and distributed without        ////
//// restriction provided that this copyright statement is not   ////
//// removed from the file and that any derivative work contains ////
//// the original copyright notice and the associated disclaimer.////
////                                                             ////
////     THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY     ////
//// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED   ////
//// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS   ////
//// FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL THE AUTHOR      ////
//// OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,         ////
//// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES    ////
//// (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE   ////
//// GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR        ////
//// BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF  ////
//// LIABILITY, WHETHER IN  CONTRACT, STRICT LIABILITY, OR TORT  ////
//// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT  ////
//// OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE         ////
//// POSSIBILITY OF SUCH DAMAGE.                                 ////
////                                                             ////
/////////////////////////////////////////////////////////////////////

//  CVS Log
//
//  $Id: i2c_master_bit_ctrl.v,v 1.11 2004/05/07 11:02:26 rherveille Exp $
//
//  $Date: 2004/05/07 11:02:26 $
//  $Revision: 1.11 $
//  $Author: rherveille $
//  $Locker:  $
//  $State: Exp $
//
// Change History:
//               $Log: i2c_master_bit_ctrl.v,v $
//               Revision 1.11  2004/05/07 11:02:26  rherveille
//               Fixed a bug where the core would signal an arbitration lost (AL bit set), when another master controls the bus and the other master generates a STOP bit.
//
//               Revision 1.10  2003/08/09 07:01:33  rherveille
//               Fixed a bug in the Arbitration Lost generation caused by delay on the (external) sda line.
//               Fixed a potential bug in the byte controller's host-acknowledge generation.
//
//               Revision 1.9  2003/03/10 14:26:37  rherveille
//               Fixed cmd_ack generation item (no bug).
//
//               Revision 1.8  2003/02/05 00:06:10  rherveille
//               Fixed a bug where the core would trigger an erroneous 'arbitration lost' interrupt after being reset, when the reset pulse width < 3 clk cycles.
//
//               Revision 1.7  2002/12/26 16:05:12  rherveille
//               Small code simplifications
//
//               Revision 1.6  2002/12/26 15:02:32  rherveille
//               Core is now a Multimaster I2C controller
//
//               Revision 1.5  2002/11/30 22:24:40  rherveille
//               Cleaned up code
//
//               Revision 1.4  2002/10/30 18:10:07  rherveille
//               Fixed some reported minor start/stop generation timing issuess.
//
//               Revision 1.3  2002/06/15 07:37:03  rherveille
//               Fixed a small timing bug in the bit controller.\nAdded verilog simulation environment.
//
//               Revision 1.2  2001/11/05 11:59:25  rherveille
//               Fixed wb_ack_o generation bug.
//               Fixed bug in the byte_controller statemachine.
//               Added headers.
//

//
/////////////////////////////////////
// Bit controller section
/////////////////////////////////////
//
// Translate simple commands into SCL/SDA transitions
// Each command has 5 states, A/B/C/D/idle
//
// start:	SCL	~~~~~~~~~~\____
//	SDA	~~~~~~~~\______
//		 x | A | B | C | D | i
//
// repstart	SCL	____/~~~~\___
//	SDA	__/~~~\______
//		 x | A | B | C | D | i
//
// stop	SCL	____/~~~~~~~~
//	SDA	==\____/~~~~~
//		 x | A | B | C | D | i
//
//- write	SCL	____/~~~~\____
//	SDA	==X=========X=
//		 x | A | B | C | D | i
//
//- read	SCL	____/~~~~\____
//	SDA	XXXX=====XXXX
//		 x | A | B | C | D | i
//

// Timing:     Normal mode      Fast mode
///////////////////////////////////////////////////////////////////////
// Fscl        100KHz           400KHz
// Th_scl      4.0us            0.6us   High period of SCL
// Tl_scl      4.7us            1.3us   Low period of SCL
// Tsu:sta     4.7us            0.6us   setup time for a repeated start condition
// Tsu:sto     4.0us            0.6us   setup time for a stop conditon
// Tbuf        4.7us            1.3us   Bus free time between a stop and start condition
//

// synopsys translate_off
//`include "timescale.v"
// synopsys translate_on

`include "i2c_master_defines.v"

module i2c_master_bit_ctrl(
    clk, rst, nReset, 
    clk_cnt, ena, cmd, cmd_ack, busy, al, din, dout,
    scl_i, scl_o, scl_oen, sda_i, sda_o, sda_oen
    );

    //
    // inputs & outputs
    //
    input clk;
    input rst;
    input nReset;
    input ena;            // core enable signal

    input [15:0] clk_cnt; // clock prescale value

    input  [3:0] cmd;
    output       cmd_ack; // command complete acknowledge
    reg cmd_ack;
    output       busy;    // i2c bus busy
    reg busy;
    output       al;      // i2c bus arbitration lost
    reg al;

    input  din;
    output dout;
    reg dout;

    // I2C lines
    input  scl_i;         // i2c clock line input
    output scl_o;         // i2c clock line output
    output scl_oen;       // i2c clock line output enable (active low)
    reg scl_oen;
    input  sda_i;         // i2c data line input
    output sda_o;         // i2c data line output
    output sda_oen;       // i2c data line output enable (active low)
    reg sda_oen;


    //
    // variable declarations
    //

    reg sSCL, sSDA;             // synchronized SCL and SDA inputs
    reg dscl_oen;               // delayed scl_oen
    reg sda_chk;                // check SDA output (Multi-master arbitration)
    reg clk_en;                 // clock generation signals
    wire slave_wait;
//    reg [15:0] cnt = clk_cnt;   // clock divider counter (simulation)
    reg [15:0] cnt;             // clock divider counter (synthesis)

    // state machine variable
    reg [16:0] c_state; 

    //
    // module body
    //

    // whenever the slave is not ready it can delay the cycle by pulling SCL low
    // delay scl_oen
    always @(posedge clk)
      dscl_oen <= #1 scl_oen;

    assign slave_wait = dscl_oen && !sSCL;


    // generate clk enable signal
    always @(posedge clk or negedge nReset)
      if(~nReset)
        begin
            cnt    <= #1 16'h0;
            clk_en <= #1 1'b1;
        end
      else if (rst)
        begin
            cnt    <= #1 16'h0;
            clk_en <= #1 1'b1;
        end
      else if ( ~|cnt || ~ena)
        if (~slave_wait)
          begin
              cnt    <= #1 clk_cnt;
              clk_en <= #1 1'b1;
          end
        else
          begin
              cnt    <= #1 cnt;
              clk_en <= #1 1'b0;
          end
      else
        begin
                cnt    <= #1 cnt - 16'h1;
            clk_en <= #1 1'b0;
        end


    // generate bus status controller
    reg dSCL, dSDA;
    reg sta_condition;
    reg sto_condition;

    // synchronize SCL and SDA inputs
    // reduce metastability risc
    always @(posedge clk or negedge nReset)
      if (~nReset)
        begin
            sSCL <= #1 1'b1;
            sSDA <= #1 1'b1;

            dSCL <= #1 1'b1;
            dSDA <= #1 1'b1;
        end
      else if (rst)
        begin
            sSCL <= #1 1'b1;
            sSDA <= #1 1'b1;

            dSCL <= #1 1'b1;
            dSDA <= #1 1'b1;
        end
      else
        begin
            sSCL <= #1 scl_i;
            sSDA <= #1 sda_i;

            dSCL <= #1 sSCL;
            dSDA <= #1 sSDA;
        end

    // detect start condition => detect falling edge on SDA while SCL is high
    // detect stop condition => detect rising edge on SDA while SCL is high
    always @(posedge clk or negedge nReset)
      if (~nReset)
        begin
            sta_condition <= #1 1'b0;
            sto_condition <= #1 1'b0;
        end
      else if (rst)
        begin
            sta_condition <= #1 1'b0;
            sto_condition <= #1 1'b0;
        end
      else
        begin
            sta_condition <= #1 ~sSDA &  dSDA & sSCL;
            sto_condition <= #1  sSDA & ~dSDA & sSCL;
        end

    // generate i2c bus busy signal
    always @(posedge clk or negedge nReset)
      if(!nReset)
        busy <= #1 1'b0;
      else if (rst)
        busy <= #1 1'b0;
      else
        busy <= #1 (sta_condition | busy) & ~sto_condition;

    // generate arbitration lost signal
    // aribitration lost when:
    // 1) master drives SDA high, but the i2c bus is low
    // 2) stop detected while not requested
    reg cmd_stop;
    always @(posedge clk or negedge nReset)
      if (~nReset)
        cmd_stop <= #1 1'b0;
      else if (rst)
        cmd_stop <= #1 1'b0;
      else if (clk_en)
        cmd_stop <= #1 cmd == `I2C_CMD_STOP;

    always @(posedge clk or negedge nReset)
      if (~nReset)
        al <= #1 1'b0;
      else if (rst)
        al <= #1 1'b0;
      else
        al <= #1 (sda_chk & ~sSDA & sda_oen) | (|c_state & sto_condition & ~cmd_stop);


    // generate dout signal (store SDA on rising edge of SCL)
    always @(posedge clk)
      if(sSCL & ~dSCL)
        dout <= #1 sSDA;

    // generate statemachine

    // nxt_state decoder
    parameter [16:0] idle    = 17'b0_0000_0000_0000_0000;
    parameter [16:0] start_a = 17'b0_0000_0000_0000_0001;
    parameter [16:0] start_b = 17'b0_0000_0000_0000_0010;
    parameter [16:0] start_c = 17'b0_0000_0000_0000_0100;
    parameter [16:0] start_d = 17'b0_0000_0000_0000_1000;
    parameter [16:0] start_e = 17'b0_0000_0000_0001_0000;
    parameter [16:0] stop_a  = 17'b0_0000_0000_0010_0000;
    parameter [16:0] stop_b  = 17'b0_0000_0000_0100_0000;
    parameter [16:0] stop_c  = 17'b0_0000_0000_1000_0000;
    parameter [16:0] stop_d  = 17'b0_0000_0001_0000_0000;
    parameter [16:0] rd_a    = 17'b0_0000_0010_0000_0000;
    parameter [16:0] rd_b    = 17'b0_0000_0100_0000_0000;
    parameter [16:0] rd_c    = 17'b0_0000_1000_0000_0000;
    parameter [16:0] rd_d    = 17'b0_0001_0000_0000_0000;
    parameter [16:0] wr_a    = 17'b0_0010_0000_0000_0000;
    parameter [16:0] wr_b    = 17'b0_0100_0000_0000_0000;
    parameter [16:0] wr_c    = 17'b0_1000_0000_0000_0000;
    parameter [16:0] wr_d    = 17'b1_0000_0000_0000_0000;

    always @(posedge clk or negedge nReset)
      if (!nReset)
        begin
            c_state <= #1 idle;
            cmd_ack <= #1 1'b0;
            scl_oen <= #1 1'b1;
            sda_oen <= #1 1'b1;
            sda_chk <= #1 1'b0;
        end
      else if (rst | al)
        begin
            c_state <= #1 idle;
            cmd_ack <= #1 1'b0;
            scl_oen <= #1 1'b1;
            sda_oen <= #1 1'b1;
            sda_chk <= #1 1'b0;
        end
      else
        begin
            cmd_ack   <= #1 1'b0; // default no command acknowledge + assert cmd_ack only 1clk cycle

            if (clk_en)
              case (c_state) // synopsys full_case parallel_case
                // idle state
                idle:
                begin
                    case (cmd) // synopsys full_case parallel_case
                      `I2C_CMD_START:
                         c_state <= #1 start_a;

                      `I2C_CMD_STOP:
                         c_state <= #1 stop_a;

                      `I2C_CMD_WRITE:
                         c_state <= #1 wr_a;

                      `I2C_CMD_READ:
                         c_state <= #1 rd_a;

                      default:
                        c_state <= #1 idle;
                    endcase

                    scl_oen <= #1 scl_oen; // keep SCL in same state
                    sda_oen <= #1 sda_oen; // keep SDA in same state
                    sda_chk <= #1 1'b0;    // don't check SDA output
                end

                // start
                start_a:
                begin
                    c_state <= #1 start_b;
                    scl_oen <= #1 scl_oen; // keep SCL in same state
                    sda_oen <= #1 1'b1;    // set SDA high
                    sda_chk <= #1 1'b0;    // don't check SDA output
                end

                start_b:
                begin
                    c_state <= #1 start_c;
                    scl_oen <= #1 1'b1; // set SCL high
                    sda_oen <= #1 1'b1; // keep SDA high
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                start_c:
                begin
                    c_state <= #1 start_d;
                    scl_oen <= #1 1'b1; // keep SCL high
                    sda_oen <= #1 1'b0; // set SDA low
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                start_d:
                begin
                    c_state <= #1 start_e;
                    scl_oen <= #1 1'b1; // keep SCL high
                    sda_oen <= #1 1'b0; // keep SDA low
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                start_e:
                begin
                    c_state <= #1 idle;
                    cmd_ack <= #1 1'b1;
                    scl_oen <= #1 1'b0; // set SCL low
                    sda_oen <= #1 1'b0; // keep SDA low
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                // stop
                stop_a:
                begin
                    c_state <= #1 stop_b;
                    scl_oen <= #1 1'b0; // keep SCL low
                    sda_oen <= #1 1'b0; // set SDA low
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                stop_b:
                begin
                    c_state <= #1 stop_c;
                    scl_oen <= #1 1'b1; // set SCL high
                    sda_oen <= #1 1'b0; // keep SDA low
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                stop_c:
                begin
                    c_state <= #1 stop_d;
                    scl_oen <= #1 1'b1; // keep SCL high
                    sda_oen <= #1 1'b0; // keep SDA low
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                stop_d:
                begin
                    c_state <= #1 idle;
                    cmd_ack <= #1 1'b1;
                    scl_oen <= #1 1'b1; // keep SCL high
                    sda_oen <= #1 1'b1; // set SDA high
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                // read
                rd_a:
                begin
                    c_state <= #1 rd_b;
                    scl_oen <= #1 1'b0; // keep SCL low
                    sda_oen <= #1 1'b1; // tri-state SDA
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                rd_b:
                begin
                    c_state <= #1 rd_c;
                    scl_oen <= #1 1'b1; // set SCL high
                    sda_oen <= #1 1'b1; // keep SDA tri-stated
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                rd_c:
                begin
                    c_state <= #1 rd_d;
                    scl_oen <= #1 1'b1; // keep SCL high
                    sda_oen <= #1 1'b1; // keep SDA tri-stated
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                rd_d:
                begin
                    c_state <= #1 idle;
                    cmd_ack <= #1 1'b1;
                    scl_oen <= #1 1'b0; // set SCL low
                    sda_oen <= #1 1'b1; // keep SDA tri-stated
                    sda_chk <= #1 1'b0; // don't check SDA output
                end

                // write
                wr_a:
                begin
                    c_state <= #1 wr_b;
                    scl_oen <= #1 1'b0; // keep SCL low
                    sda_oen <= #1 din;  // set SDA
                    sda_chk <= #1 1'b0; // don't check SDA output (SCL low)
                end

                wr_b:
                begin
                    c_state <= #1 wr_c;
                    scl_oen <= #1 1'b1; // set SCL high
                    sda_oen <= #1 din;  // keep SDA
                    sda_chk <= #1 1'b1; // check SDA output
                end

                wr_c:
                begin
                    c_state <= #1 wr_d;
                    scl_oen <= #1 1'b1; // keep SCL high
                    sda_oen <= #1 din;
                    sda_chk <= #1 1'b1; // check SDA output
                end

                wr_d:
                begin
                    c_state <= #1 idle;
                    cmd_ack <= #1 1'b1;
                    scl_oen <= #1 1'b0; // set SCL low
                    sda_oen <= #1 din;
                    sda_chk <= #1 1'b0; // don't check SDA output (SCL low)
                end

              endcase
        end


    // assign scl and sda output (always gnd)
    assign scl_o = 1'b0;
    assign sda_o = 1'b0;

endmodule
